.TH offwaketime 8  "2016-01-30" "USER COMMANDS"
.SH NAME
offwaketime \- Summarize blocked time by off-CPU stack + waker stack. Uses Linux eBPF/bcc.
.SH SYNOPSIS
.B offwaketime [\-h] [\-p PID | \-t TID | \-u | \-k] [\-U | \-K] [\-f] [\-\-stack-storage-size STACK_STORAGE_SIZE] [\-m MIN_BLOCK_TIME] [\-M MAX_BLOCK_TIME] [\-\-state STATE] [duration]
.SH DESCRIPTION
This program shows kernel stack traces and task names that were blocked and
"off-CPU", along with the stack traces and task names for the threads that woke
them, and the total elapsed time from when they blocked to when they were woken
up.  This combines the summaries from both the offcputime and wakeuptime tools.
The time measurement will be very similar to off-CPU time, however, off-CPU time
may include a little extra time spent waiting on a run queue to be scheduled.
The combined stacks, task names, and total time is summarized in kernel context
for efficiency, using an eBPF map.

The output summary will further help you identify reasons why threads
were blocking, and quantify the time from when they were blocked to woken up.
This spans all types of blocking activity: disk I/O, network I/O, locks, page
faults, swapping, sleeping, involuntary context switches, etc.

This is complementary to CPU profiling (e.g., CPU flame graphs) which shows
the time spent on-CPU. This shows the time spent blocked off-CPU, and the
output, especially the -f format, can be used to generate an "off-wake time
flame graph".

See http://www.brendangregg.com/FlameGraphs/offcpuflamegraphs.html

.SH REQUIREMENTS
CONFIG_BPF and bcc.
.SH OPTIONS
.TP
\-h
Print usage message.
.TP
\-f
Print output in folded stack format.
.TP
\-p PID
Trace this process ID only (filtered in-kernel). Can be a comma separated list
of PIDS.
.TP
\-t TID
Trace this thread ID only (filtered in-kernel). Can be a comma separated list
of TIDS.
.TP
\-u
Only trace user threads (no kernel threads).
.TP
\-k
Only trace kernel threads (no user threads).
.TP
\-U
Show stacks from user space only (no kernel space stacks).
.TP
\-K
Show stacks from kernel space only (no user space stacks).
.TP
\-\-stack-storage-size STACK_STORAGE_SIZE
Change the number of unique stack traces that can be stored and displayed.
.TP
duration
Duration to trace, in seconds.
.TP
\-m MIN_BLOCK_TIME
The amount of time in microseconds over which we store traces (default 1)
.TP
\-M MAX_BLOCK_TIME
The amount of time in microseconds under which we store traces (default U64_MAX)
.TP
\-\-state
Filter on this thread state bitmask (eg, 2 == TASK_UNINTERRUPTIBLE).
See include/linux/sched.h for states.
.SH EXAMPLES
.TP
Trace all thread blocking events, and summarize (in-kernel) by user and kernel off-CPU stack trace, waker stack traces, task names, and total blocked time:
#
.B offwaketime
.TP
Trace for 5 seconds only:
#
.B offwaketime 5
.TP
Trace for 5 seconds, and emit output in folded stack format (suitable for flame graphs), user-mode threads only:
#
.B offwaketime -fu 5
.TP
Trace PID 185 only:
#
.B offwaketime -p 185
.SH OVERHEAD
This summarizes unique stack trace pairs in-kernel for efficiency, allowing it
to trace a higher rate of events than methods that post-process in user space.
The stack trace and time data is only copied to user space once, when the output
is printed. While these techniques greatly lower overhead, scheduler events are
still a high frequency event, as they can exceed 1 million events per second,
and so caution should still be used. Test before production use.

If the overhead is still a problem, take a look at the min block option.
If your aim is to chase down longer blocking events, then this could
be increased to filter shorter blocking events, further lowering overhead.
.SH SOURCE
This is from bcc.
.IP
https://github.com/iovisor/bcc
.PP
Also look in the bcc distribution for a companion _examples.txt file containing
example usage, output, and commentary for this tool.
.SH OS
Linux
.SH STABILITY
Unstable - in development.
.SH AUTHOR
Brendan Gregg
.SH SEE ALSO
offcputime(8), wakeuptime(8)
